Relationship between shear wave velocity and liquefaction resistance of coral sand in the South China Sea
WANG Yunlong1, 2, WANG Yide1, 2, 3*, CHEN Longwei1, 2, MA Jiajun1, 2, LIU Huida4, WANG Luan5, ZHANG Wenbin6, YUAN Xiaoming1, 2
(1. Key Laboratory of Earthquake Engineering and Engineering Vibration, Institute of Engineering Mechanics, China Earthquake Administration, Harbin, Heilongjiang 150080, China; 2. Key Laboratory of Earthquake Disaster Mitigation, Ministry of
Emergency Management, Institute of Engineering Mechanics, China Earthquake Administration, Harbin, Heilongjiang
150080, China; 3. Provincial Key Laboratory of Marine Engineering Geology and the Environment, Ocean University
of China, Qingdao, Shandong 266100, China; 4. China Construction Infrastructure Co., Ltd., Beijing 100044, China;
5. China Overseas Land & Investment Ltd., Shenzhen, Guangdong 518048, China; 6. Shanghai Municipal
Engineering Design Institute (Group) Co., Ltd., Shanghai 200092, China)
Abstract:Coral sand deposits in the islands and reefs of the South China Sea are vulnerable to seismic liquefaction. Shear wave velocity provides a rapid and non-destructive method for assessing liquefaction potential; however, existing criteria, primarily developed for quartz sands, exhibit limited applicability to coral sands. This study aims to establish a specific relationship between shear wave velocity and cyclic resistance ratio for coral sand. A series of cyclic undrained triaxial tests and bender element tests were conducted using a GDS dynamic triaxial system on saturated coral sand from the South China Sea and comparable quartz sand. Systematic measurements of cyclic resistance and shear wave velocity were obtained for both materials, leading to the development of a quantitative model relating shear wave velocity to cyclic resistance for coral sand. The validity and engineering applicability of the proposed model were further validated through a case study of typical liquefaction sites, resulting in an empirical equation for the critical shear wave velocity of coral sand. The results indicate a strong correlation between shear wave velocity and cyclic resistance ratio in coral sand, with coral sand exhibiting significantly higher shear wave velocity than quartz sand at equivalent cyclic resistance ratio levels, thereby confirming their intrinsic mechanical differences. The proposed model effectively characterizes the liquefaction resistance of coral sand under varying seismic intensities and can accurately delineate liquefied layers in case analyses. This research provides a valuable reference for seismic safety assessments and foundation design in coral sand sites, such as islands and ports in the South China Sea.
汪云龙1,2,王义德1,2,3*,陈龙伟1,2,马佳钧1,2,刘荟达4,王 鸾5,张文彬6,袁晓铭1,2. 南海珊瑚砂剪切波速与抗液化强度关系研究[J]. 岩石力学与工程学报, 2026, 45(2): 613-625.
WANG Yunlong1, 2, WANG Yide1, 2, 3*, CHEN Longwei1, 2, MA Jiajun1, 2, LIU Huida4, WANG Luan5, ZHANG Wenbin6, YUAN Xiaoming1, 2. Relationship between shear wave velocity and liquefaction resistance of coral sand in the South China Sea. , 2026, 45(2): 613-625.
[1] 袁晓铭,张文彬,段志刚,等. 珊瑚土工程场地地震液化特征解析[J]. 岩石力学与工程学报,2019,38(增2):3 799–3 811.(YUAN Xiaoming,ZHANG Wenbin,DUAN Zhigang,et al. Analysis for characteristics of seismic liquefaction in engineering sites of coralline soils[J]. Chinese Journal of Rock Mechanics and Engineering,2019,38(Supp.2):3 799–3 811.(in Chinese))
[2] SHAHNAZARI H,JAFARIAN Y,TUTUNCHIAN M A,et al. Probabilistic assessment of liquefaction occurrence in calcareous fill materials of Kawaihae Harbor,Hawaii[J]. International Journal of Geomechanics,2016,16(6):05016001.
[3] 马成昊,朱长歧,瞿 茹,等. 中国南海珊瑚砂的多尺度颗粒形貌特征分析[J]. 岩土力学,2023,44(增1):117–126.(MA Chenghao,ZHU Changqi,QU Ru,et al. Multi-scale particle morphology analysis of coral sand in South China Sea[J]. Rock and Soil Mechanics,2023,44(Supp.1):117–126.(in Chinese))
[4] 傅 华,凌 华,蔡正银. 粗颗粒土颗粒破碎影响因素试验研究[J]. 河海大学学报:自然科学版,2009,37(1):75–79.(FU Hua,LING Hua,CAI Zhengyin. Influencing factors for particle breakage of coarse grained soil[J]. Journal of Hohai University:Natural Science,2009,37(1):75–79.(in Chinese))
[5] 蔡正银,陈元义,朱 洵,等. 级配对珊瑚砂颗粒破碎与变形特性的影响[J]. 岩土工程学报,2023,45(4):661–670.(CAI Zhengyin,CHEN Yuanyi,ZHU Xun,et al. Influences of gradation on particle breakage and deformation characteristics of coral sand[J]. Chinese Journal of Geotechnical Engineering,2023,45(4):661–670.(in Chinese))
[6] CHOCK G,ROBERTSON I,NICHOLSON P,et al. Compilation of observations of the October 15,2006,Kiholo Bay(Mw 6.7) and Mahukona(Mw 6.0) earthquakes,Hawaii[J]. Earthquake Engineering Research Institute,2006,31:1–53.
[7] GREEN R A,OLSON S M,COX B R,et al. Geotechnical aspects of failures at Port-au-Prince seaport during the 12 January 2010 Haiti earthquake[J]. Earthquake Spectra,2011,27(Supp.1):43–65.
[8] MEDLEY E W. Geological engineering reconnaissance of damage caused by the October 15,2006 Hawaii earthquakes[J]. ISSMGE International Journal of Geoengineering Case Histories,2007,1(2):89–135.
[9] MEJIA L H,YEUNG M R. Liquefaction of coralline soils during the 1993 Guam earthquake[C]// Proceedings of the ASCE Earthquake-Induced Movements and Seismic Remediation of Existing Foundations and Abutments. San Diego,California:[s. n.],1995:33–48.
[10] RATHJE E,BACHHUBER J,COX B,et al. Geotechnical engineering reconnaissance of the 2010 Haiti earthquake[R]. [S. l.]:GEER Association,2010.
[11] SWAN S W,HARRIS S K. The Island of Guam earthquake of august 8,1993[R]. Buffalo:National Center for Earthquake Engineering Research,State University of New York,1993.
[12] ZHOU Y G,SUN Z B,CHEN J,et al. Shear wave velocity-based evaluation and design of stone column improved ground for liquefaction mitigation[J]. Earthquake Engineering and Engineering Vibration,2017,16(2):247–261.
[13] ZHOU Y G,XIA P,LING D S,et al. Liquefaction case studies of gravelly soils during the 2008 Wenchuan earthquake[J]. Engineering geology,2020,274:105691.
[14] YANG Y,WEI Y T. A new shear wave velocity-based liquefaction probability model using logistic regression:emphasizing fines content optimization[J]. Applied Sciences,2024,14(15):6 793.
[15] 杨 洋,孙 锐. 基于剪切波速的液化可能性等级评估表法[J]. 岩土力学,2023,44(增1):634–644.(YANG Yang,SUN Rui. Liquefaction probability criteria table based on shear wave velocity[J]. Rock and Soil Mechanics,2023,44(Supp.1):634–644.(in Chinese))
[16] SHEN M F,CHEN Q S,ZHANG J,et al. Predicting liquefaction probability based on shear wave velocity:an update[J]. Bulletin of Engineering Geology and the Environment,2016,75(3):1 199–1 214.
[17] CHEN G X,KONG M Y,KHOSHNEVISAN S,et al. Calibration of Vs-based empirical models for assessing soil liquefaction potential using expanded database[J]. Bulletin of Engineering Geology and the Environment,2019,78(2):945–957.
[18] CAI G J,LIU S Y,PUPPALA A J. Liquefaction assessments using seismic piezocone penetration(SCPTU) test investigations in Tangshan region in China[J]. Soil Dynamics and Earthquake Engineering,2012,41:141–150.
[19] 周燕国,周鑫辉,桑毅佳,等. 考虑沉积时间效应的原位砂土抗液化强度剪切波速评价[J]. 岩土工程学报,2023,45(增2):19–24. (ZHOU Yanguo,ZHOU Xinhui,SANG Yijia,et al. Shear wave velocity-based evaluation of liquefaction resistance of in-situ sand with aging effects[J]. Chinese Journal of Geotechnical Engineering,2023,45(Supp.2):19–24.(in Chinese))
[20] DOBRY R,BORCHERDT R D,CROUSE C B,et al. New site coefficients and site classification system used in recent building seismic code provisions[J]. Earthquake Spectra,2000,16(1):41–67.
[21] WU Q,LIU Q F,ZHUANG H Y,et al. Experimental investigation of dynamic shear modulus of saturated marine coral sand[J]. Ocean Engineering,2022,264:112412.
[22] LIANG K,CHEN G X,DU X L,et al. A unified formula for small-strain shear modulus of sandy soils based on extreme void ratios[J]. Journal of Geotechnical and Geoenvironmental Engineering,2023,149(2):04022127.
[23] KAYEN R,MOSS R E S,THOMPSON E M,et al. Shear-wave velocity-based probabilistic and deterministic assessment of seismic soil liquefaction potential[J]. Journal of Geotechnical and Geoenvironmental Engineering,2013,139(3):407–419.
[24] ANDRUS R D,STOKOE II K H. Liquefaction resistance of soils from shear-wave velocity[J]. Journal of Geotechnical and Geoenvironmental Engineering,2000,126(11):1 015–1 025.
[25] American Society of Civil Engineers. ASCE/SEI 7-22 Minimum design loads and associated criteria for buildings and other structures[S]. Reston,Virginia:American Society of Civil Engineers,2022.
[26] National Institute of Building Sciences. FEMA 450 NEHRP recommended provisions for seismic regulations for new buildings and other structures[S]. Washington,DC:Federal Emergency Management Agency,2004.
[27] 中华人民共和国行业标准编写组. TBJ1—88建筑地基基础设计规范[S]. 天津:天津市住房和城乡建设委员会,1988.(The Professional Standards Compilation Group of People?s Republic of China. TBJ1—88 Code for Design of Building Foundation[S]. Tianjin:Tianjin Housing and Urban-Rural Construction Commission,1988.(in Chinese))
[28] 汪云龙,袁晓铭,孙 锐,等. 珊瑚吹填土初始剪切模量试验研究[J]. 中国海洋大学学报:自然科学版,2017,47(10):36–41. (WANG Yunlong,YUAN Xiaoming,SUN Rui,et al. Experimental investigation on initial shear modulus of coral reclaimed soil[J]. Periodical of Ocean University of China,2017,47(10):36–41.(in Chinese))
[29] 郭 桢,蒲 建,卢劲锴,等. 南海西沙岛礁非饱和珊瑚砂共振柱–弯曲元试验研究[J]. 工程地质学报,2023,31(5):1 552–1 562. (GUO Zhen,PU Jian,LU Jinkai,et al. Resonant column and bender element tests of unsaturated coral sand on Xisha islands in South China Sea[J]. Journal of Engineering Geology,2023,31(5):1 552–1 562. (in Chinese))
[30] 施周桓,赵力左,陈鹏骏,等. 非等向固结条件下含砾粒珊瑚土动力液化特性试验研究[J]. 岩土工程学报,2025,47(增1):132–137. (ZHOU Shiheng,ZHAO Lizuo,CHEN Pengjun,et al. Cyclic liquefaction behavior of coral sand-gravel soil under anisotropic consolidation conditions[J]. Chinese Journal of Geotechnical Engineering,2025,47(Supp.1):132–137.(in Chinese))
[31] 史金权,肖 杨,刘汉龙,等. 钙质砂小应变初始剪切模量试验研究[J]. 岩土工程学报,2022,44(2):324–333.(SHI Jinquan,XIAO Yang,LIU Hanlong,et al. Experimental study on small-strain shear modulus of calcareous sand[J]. Chinese Journal of Geotechnical Engineering,2022,44(2):324–333.(in Chinese))
[32] 刘汉龙,张 宇,郭 伟,等. 微生物加固钙质砂动孔压模型研究[J]. 岩石力学与工程学报,2021,40(4):790–801.(LIU Hanlong,ZHANG Yu,GUO Wei,et al. A prediction model of dynamic pore water pressure for MICP-treated calcareous sand[J]. Chinese Journal of Rock Mechanics and Engineering,2021,40(4):790–801.(in Chinese))
[33] WANG Y D,WANG Y L,LIU H D,et al. Experimental investigation of influencing factors on shear wave velocity in coral sand[J]. Soil Dynamics and Earthquake Engineering,2026,200:109910.
[34] 虞海珍,赵文光,汪 稔,等. 复杂应力状态下钙质砂的动强度[J]. 华中科技大学学报:城市科学版,2005,22(1):40–43.(YU Haizhen,ZHAO Wenguang,WANG Ren,et al. Dynamic strength of carbonate sand in complex stress state[J]. Journal of Huazhong University of Science and Technology:Urban Science,2005,22(1):40–43.(in Chinese))
[35] 虞海珍,汪 稔. 钙质砂动强度试验研究[J]. 岩土力学,1999,20(4):6–11.(YU Haizhen,WANG Ren. The cyclic strength test research on calcareous sand[J]. Rock and Soil Mechanics,1999,20(4):6–11.(in Chinese))
[36] 许成顺,王 冰,杜修力,等. 循环加载频率对砂土液化模式的影响试验研究[J]. 土木工程学报,2021,54(11):109–118.(XU Chengshun,WANG Bing,DU Xiuli,et al. Experimental study on effect of cyclic loading frequency on liquefaction mode of sand[J]. China Civil Engineering Journal,2021,54(11):109–118.(in Chinese))
[37] 秦 悠,杜歆宇,马维嘉,等. 不同初始剪应力下饱和珊瑚砂的液化特性[J]. 哈尔滨工程大学学报,2025,46(2):197–204.(QIN You,DU Xinyu,MA Weijia,et al. Liquefaction characteristics of saturated coral sand under various initial shear stresses[J]. Journal of Harbin Engineering University,2025,46(2):197–204.(in Chinese))
[38] 吴 琪,王路阳,刘启菲,等. 基于剪切应变特征的饱和珊瑚砂超静孔压发展模型试验研究[J]. 岩土工程学报,2023,45(10):2 091–2 099.(WU Qi,WANG Luyang,LIU Qifei,et al. Experimental study on development model of excess pore pressure for saturated coral sand based on shear strain characteristics[J]. Chinese Journal of Geotechnical Engineering,2023,45(10):2 091–2 099.(in Chinese))
[39] 马维嘉,陈国兴,吴 琪. 复杂加载条件下珊瑚砂抗液化强度试验研究[J]. 岩土力学,2020,41(2):535–542.(MA Weijia,CHEN Guoxing,WU Qi. Experimental study on liquefaction resistance of coral sand under complex loading conditions[J]. Rock and Soil Mechanics,2020,41(2):535–542.(in Chinese))
[40] 刘 抗,陈国兴,吴 琪,等. 循环加载方向对饱和珊瑚砂液化特性的影响[J]. 岩土力学,2021,42(7):1 951–1 960.(LIU Kang,CHEN Guoxing,WU Qi,et al. Effects of cyclic loading directions on liquefaction characteristics of saturated coral sand[J]. Rock and Soil Mechanics,2021,42(7):1 951–1 960.(in Chinese))
[41] 梁 珂,陈国兴,刘 抗,等. 饱和珊瑚砂最大动剪切模量的循环加载衰退特性及预测模型[J]. 岩土力学,2020,41(2):601–611. (LIANG Ke,CHEN Guoxing,LIU Kang,et al. Degradation properties and prediction model of maximum shear modulus of saturated coral sand under cyclic triaxial loading[J]. Rock and Soil Mechanics,2020,41(2):601–611.(in Chinese))
[42] 王义德,汪云龙,刘荟达,等. 控制饱和度的珊瑚砂振动台液化模型试验研究[J]. 地震工程与工程振动,2024,44(6):117–124. (WANG Yide,WANG Yunlong,LIU Huida,et al. Study on the shaking table liquefaction model test of coral sand with controlled saturation[J]. Earthquake Engineering and Engineering Dynamics,2024,44(6):117–124.(in Chinese))
[43] 王 鸾,汪云龙,袁晓铭,等. 人工场地吹填珊瑚土抗液化强度大粒径动三轴试验研究[J]. 岩土力学,2021,42(10):2 819–2 829. (WANG Luan,WANG Yunlong,YUAN Xiaoming,et al. Experimental study on liquefaction resistance of hydraulic fill coralline soils at artificial sites based on large-scale dynamic triaxial apparatus[J]. Rock and Soil Mechanics,2021,42(10):2 819–2 829.(in Chinese))
[44] 王义德. 珊瑚砂液化强度理论与判别方法试验研究[博士学位论文][D]. 哈尔滨:中国地震局工程力学研究所,2024.(WANG Yide. Experimental study on the liquefaction strength theory and assessment method of coral sand[Ph. D. Thesis][D]. Harbin:Institute of Engineering Mechanics,China Earthquake Administration,2024.(in Chinese))
[45] WANG Y D,WANG Y L,WANG L,et al. Effects of membrane compliance on the normal-scale triaxial cyclic liquefaction test results of saturated coral sand[J]. Soil Dynamics and Earthquake Engineering,2023,171:107983.
[46] 王 鸾. 珊瑚土液化特性研究[博士学位论文][D]. 哈尔滨:中国地震局工程力学研究所,2021.(WANG Luan. Liquefaction Characteristics of coralline soils[Ph. D. Thesis][D]. Harbin:Institute of Engineering Mechanics,China Earthquake Administration,2021.(in Chinese))
[47] 吴 杨,崔 杰,李 能,等. 岛礁吹填珊瑚砂力学行为与颗粒破碎特性试验研究[J]. 岩土力学,2020,41(10):3 181–3 191.(WU Yang,CUI Jie,LI Neng,et al. Experimental study on the mechanical behavior and particle breakage characteristics of hydraulic filled coral sand on a coral reef island in the South China Sea[J]. Rock and Soil Mechanics,2020,41(10):3 181–3 191.(in Chinese))
[48] 李 能,吴 杨,周福霖,等. 岛礁吹填珊瑚砂不排水单调和循环剪切特性试验[J]. 中国公路学报,2023,36(8):152–161.(LI Neng,WU Yang,ZHOU Fulin,et al. Experiment of undrained monotonic and cyclic shear characteristics of hydraulic filled coral sand from reef island[J]. China Journal of Highway and Transport,2023,36(8):152–161.(in Chinese))
[49] 吴 杨,崔 杰,李 晨,等. 细粒含量对岛礁吹填珊瑚砂最大动剪切模量影响的试验研究[J]. 岩石力学与工程学报,2022,41(1):205–216.(WU Yang,CUI Jie,LI Chen,et al. Experimental study on the effect of fines on the maximum dynamic shear modulus of coral sand in a hydraulic fill island-reef[J]. Chinese Journal of Rock Mechanics and Engineering,2022,41(1):205–216.(in Chinese))
[50] 吕亚茹,丁思超,李 欣,等. 钙质砂循环剪切特性及抗剪强度弱化机制[J]. 岩石力学与工程学报,2024,43(11):2 811–2 822.(LV Yaru,DING Sichao,LI Xin,et al. Cyclic shear characteristics and shear strength weakening mechanism of calcareous sand[J]. Chinese Journal of Rock Mechanics and Engineering,2024,43(11):2 811–2 822.(in Chinese))
[51] 陈平山,吕卫清,梁小丛,等. 含细粒珊瑚土抗液化特性试验研究[J]. 岩土力学,2023,44(2):337–344.(CHEN Pingshan,LV Weiqing,LIANG Xiaocong,et al. Experimental study on liquefaction resistance characteristics of fine-grained coralline soils[J]. Rock and Soil Mechanics,2023,44(2):337–344.(in Chinese))
[52] AKOSAH S,ZHOU L,CHEN J F,et al. Undrained dynamic behavior of geogrid-reinforced coral sand[J]. Marine Georesources and Geotechnology,2025,43(2):244–259.
[53] YOUD T L,IDRISS I M. Liquefaction resistance of soils:summary report from the 1996 NCEER and 1998 NCEER/NSF workshops on evaluation of liquefaction resistance of soils[J]. Journal of Geotechnical and Geoenvironmental Engineering,2001,127(4):297–313.
[54] SEED H B,IDRISS I M. Simplified procedure for evaluating soil liquefaction potential[J]. Journal of the Soil Mechanics and Foundations Division,1971,97(9):1 249–1 273.
[55] ARANGO I. Magnitude scaling factors for soil liquefaction evaluations[J]. Journal of Geotechnical Engineering,1996,122(11):929–936.
[56] IDRISS I M. An update of the Seed-Idriss simplified procedure for evaluating liquefaction potential[C]// TRB Workshop on New Approaches to Liquefaction Analysis. Washington,DC:Federal Highway Administration. 1999:FHWA-RD–99–165.
[57] BAXTER C D P,BRADSHAW A S,GREEN R A,et al. Correlation between cyclic resistance and shear-wave velocity for providence silts[J]. Journal of Geotechnical and Geoenvironmental Engineering,2008,134(1):37–46.
[58] 姜 朴,孙德安. 砂土的共振柱试验与液化剪应力[J]. 水利学报,1987,(7):68–70.(JIANG Pu,SUN Dean. Resonance column test and liquefaction shear stress of sandy soil[J]. Journal of Hydraulic Engineering,1987,(7):68–70.(in Chinese))
[59] 石兆吉,郁寿松. 砂性土剪切波速与液化强度的关系[J]. 世界地震工程,1991,(3):16–23.(SHI Zhaoji,YU Shousong. The relationship between shear wave velocity and liquefaction intensity in sandy soil[J]. World Earthquake Engineering,1991,(3):16–23.(in Chinese))
[60] SEED H B. Soil liquefaction and cyclic mobility evaluation for level ground during earthquakes[J]. Journal of the Geotechnical Engineering Division,1979,105(2):201–255.
[61] FUHRIMAN M D. Crosshole seismic tests at two northern California sites affected by the 1989 Loma Prieta earthquake[M. S. Thesis][D]. Austin:University of Texas at Austin,1993.
[62] BRADY A G,SHAKAL A F. The Lorna Prieta,California,Earthquake of October 17,1989-Strong Ground Motion[C]// U.S. Geological Survey Professional Paper. Washington DC:United States Government Printing Office,1994:1 551–C.
[63] DE ALBA P,BENOIT J,PASS D G,et al. The Lorna Prieta,California,Earthquake of October 17,1989-Deep instrumentation array at the Treasure Island naval station[C]// U.S. Geological Survey Professional Paper. Washington DC:United States Government Printing Office,1994:1 550–A.
[64] DE ALBA P,FARIS J. Workshop on future research deep instrumentation array,Treasure Island NGES,July 27,1996[R]. Durham:University of New Hampshire,1996.
[65] 中华人民共和国国家标准编写组. GB 50011—2010建筑抗震设计规范[S]. 北京:中国建筑工业出版社,2010.(The National Standards Compilation Group of People?s Republic of China. GB 50011—2010 Code for seismic design of buildings[S]. Beijing:China Architecture and Building Press,2010.(in Chinese))
[66] 袁晓铭,王 海,曹振中,等. 汶川地震砾性土液化场地特征解析[J]. 地球物理学报,2017,60(7):2 733–2 743.(YUAN Xiaoming,WANG Hai,CAO Zhenzhong,et al. Interpretation of characteristics of gravelly soils sites that liquefied in Wenchuan earthquake[J]. Chinese Journal of Geophysics,2017,60(7):2 733–2 743.(in Chinese))
[67] 石兆吉,郁寿松,丰万玲. 土壤液化势的剪切波速判别法[J]. 岩土工程学报,1993,15(1):74–80.(SHI Zhaoji,YU Shousong,FENG Wanling. The method for judging the shear wave velocity of soil liquefaction potential[J]. Chinese Journal of Geotechnical Engineering,1993,15(1):74–80.(in Chinese))
[68] 王 克,孙 锐,袁晓铭. 动剪应力折减系数影响因素及计算公式[J]. 岩石力学与工程学报,2018,37(1):177–189.(WANG Ke,SUN Rui,YUAN Xiaoming. Influence factors and formula for dynamic stress reduction coefficient[J]. Chinese Journal of Rock Mechanics and Engineering,2018,37(1):177–189.(in Chinese))
2026, Vol. 45 
